/*
 * $Id$
 */

package edu.jas.gb;


import java.util.List;
import java.util.Map;

import edu.jas.poly.ExpVector;
import edu.jas.poly.GenSolvablePolynomial;
import edu.jas.structure.RingElem;


/**
 * Solvable polynomial Reduction algorithm. Implements left, right normalform.
 * @param <C> coefficient type
 * @author Heinz Kredel
 */

public class SolvableReductionSeq<C extends RingElem<C>> extends SolvableReductionAbstract<C> {


    //private static final Logger logger = Logger.getLogger(SolvableReductionSeq.class);


    /**
     * Constructor.
     */
    public SolvableReductionSeq() {
    }


    /**
     * Left Normalform.
     * @param Ap solvable polynomial.
     * @param Pp solvable polynomial list.
     * @return left-nf(Ap) with respect to Pp.
     */
    @SuppressWarnings("unchecked")
    public GenSolvablePolynomial<C> leftNormalform(List<GenSolvablePolynomial<C>> Pp,
            GenSolvablePolynomial<C> Ap) {
        if (Pp == null || Pp.isEmpty()) {
            return Ap;
        }
        if (Ap == null || Ap.isZERO()) {
            return Ap;
        }
        int l;
        Map.Entry<ExpVector, C> m;
        GenSolvablePolynomial<C>[] P;
        synchronized (Pp) {
            l = Pp.size();
            P = (GenSolvablePolynomial<C>[]) new GenSolvablePolynomial[l];
            //P = Pp.toArray();
            for (int j = 0; j < Pp.size(); j++) {
                P[j] = Pp.get(j);
            }
        }
        int i;
        ExpVector[] htl = new ExpVector[l];
        Object[] lbc = new Object[l]; // want <C>
        GenSolvablePolynomial<C>[] p = new GenSolvablePolynomial[l];
        int j = 0;
        for (i = 0; i < l; i++) {
            p[i] = P[i];
            m = p[i].leadingMonomial();
            if (m != null) {
                p[j] = p[i];
                htl[j] = m.getKey();
                lbc[j] = m.getValue();
                j++;
            }
        }
        l = j;
        ExpVector e;
        C a;
        boolean mt = false;
        GenSolvablePolynomial<C> R = Ap.ring.getZERO();

        //GenSolvablePolynomial<C> T = null;
        GenSolvablePolynomial<C> Q = null;
        GenSolvablePolynomial<C> S = Ap;
        while (S.length() > 0) {
            m = S.leadingMonomial();
            e = m.getKey();
            //logger.info("red = " + e);
            a = m.getValue();
            for (i = 0; i < l; i++) {
                mt = e.multipleOf(htl[i]);
                if (mt)
                    break;
            }
            if (!mt) {
                //logger.debug("irred");
                //T = new OrderedMapPolynomial( a, e );
                R = (GenSolvablePolynomial<C>) R.sum(a, e);
                S = (GenSolvablePolynomial<C>) S.subtract(a, e);
                // System.out.println(" S = " + S);
            } else {
                //logger.debug("red");
                e = e.subtract(htl[i]);
                //a = a.divide( (C)lbc[i] );
                Q = p[i].multiplyLeft(e);
                a = a.divide(Q.leadingBaseCoefficient());
                Q = Q.multiplyLeft(a);
                S = (GenSolvablePolynomial<C>) S.subtract(Q);
            }
        }
        return R;
    }


    /**
     * LeftNormalform with recording.
     * @param row recording matrix, is modified.
     * @param Pp a polynomial list for reduction.
     * @param Ap a polynomial.
     * @return nf(Pp,Ap), the left normal form of Ap wrt. Pp.
     */
    @SuppressWarnings("unchecked")
    public GenSolvablePolynomial<C> leftNormalform(List<GenSolvablePolynomial<C>> row,
            List<GenSolvablePolynomial<C>> Pp, GenSolvablePolynomial<C> Ap) {
        if (Pp == null || Pp.isEmpty()) {
            return Ap;
        }
        if (Ap == null || Ap.isZERO()) {
            return Ap;
        }
        int l = Pp.size();
        GenSolvablePolynomial<C>[] P = (GenSolvablePolynomial<C>[]) new GenSolvablePolynomial[l];
        synchronized (Pp) {
            //P = Pp.toArray();
            for (int i = 0; i < Pp.size(); i++) {
                P[i] = Pp.get(i);
            }
        }
        ExpVector[] htl = new ExpVector[l];
        Object[] lbc = new Object[l]; // want <C>
        GenSolvablePolynomial<C>[] p = (GenSolvablePolynomial<C>[]) new GenSolvablePolynomial[l];
        Map.Entry<ExpVector, C> m;
        int j = 0;
        int i;
        for (i = 0; i < l; i++) {
            p[i] = P[i];
            m = p[i].leadingMonomial();
            if (m != null) {
                p[j] = p[i];
                htl[j] = m.getKey();
                lbc[j] = m.getValue();
                j++;
            }
        }
        l = j;
        ExpVector e;
        C a;
        boolean mt = false;
        GenSolvablePolynomial<C> zero = Ap.ring.getZERO();
        GenSolvablePolynomial<C> R = Ap.ring.getZERO();

        GenSolvablePolynomial<C> fac = null;
        // GenSolvablePolynomial<C> T = null;
        GenSolvablePolynomial<C> Q = null;
        GenSolvablePolynomial<C> S = Ap;
        while (S.length() > 0) {
            m = S.leadingMonomial();
            e = m.getKey();
            a = m.getValue();
            for (i = 0; i < l; i++) {
                mt = e.multipleOf(htl[i]);
                if (mt)
                    break;
            }
            if (!mt) {
                //logger.debug("irred");
                R = (GenSolvablePolynomial<C>) R.sum(a, e);
                S = (GenSolvablePolynomial<C>) S.subtract(a, e);
                // System.out.println(" S = " + S);
                // throw new RuntimeException("Syzygy no leftGB");
            } else {
                e = e.subtract(htl[i]);
                //logger.info("red div = " + e);
                //a = a.divide( (C)lbc[i] );
                //Q = p[i].multiplyLeft( a, e );
                Q = p[i].multiplyLeft(e);
                a = a.divide(Q.leadingBaseCoefficient());
                Q = Q.multiplyLeft(a);
                S = (GenSolvablePolynomial<C>) S.subtract(Q);
                fac = row.get(i);
                if (fac == null) {
                    fac = (GenSolvablePolynomial<C>) zero.sum(a, e);
                } else {
                    fac = (GenSolvablePolynomial<C>) fac.sum(a, e);
                }
                row.set(i, fac);
            }
        }
        return R;
    }


    /**
     * Right Normalform.
     * @param Ap solvable polynomial.
     * @param Pp solvable polynomial list.
     * @return right-nf(Ap) with respect to Pp.
     */
    @SuppressWarnings("unchecked")
    public GenSolvablePolynomial<C> rightNormalform(List<GenSolvablePolynomial<C>> Pp,
            GenSolvablePolynomial<C> Ap) {
        if (Pp == null || Pp.isEmpty()) {
            return Ap;
        }
        if (Ap == null || Ap.isZERO()) {
            return Ap;
        }
        int l;
        Map.Entry<ExpVector, C> m;
        GenSolvablePolynomial<C>[] P;
        synchronized (Pp) {
            l = Pp.size();
            P = (GenSolvablePolynomial<C>[]) new GenSolvablePolynomial[l];
            //P = Pp.toArray();
            for (int j = 0; j < Pp.size(); j++) {
                P[j] = Pp.get(j);
            }
        }
        int i;
        ExpVector[] htl = new ExpVector[l];
        Object[] lbc = new Object[l]; // want <C>
        GenSolvablePolynomial<C>[] p = (GenSolvablePolynomial<C>[]) new GenSolvablePolynomial[l];
        int j = 0;
        for (i = 0; i < l; i++) {
            p[i] = P[i];
            m = p[i].leadingMonomial();
            if (m != null) {
                p[j] = p[i];
                htl[j] = m.getKey();
                lbc[j] = m.getValue();
                j++;
            }
        }
        l = j;
        ExpVector e;
        C a;
        boolean mt = false;
        GenSolvablePolynomial<C> R = Ap.ring.getZERO();

        //GenSolvablePolynomial<C> T = null;
        GenSolvablePolynomial<C> Q = null;
        GenSolvablePolynomial<C> S = Ap;
        while (S.length() > 0) {
            m = S.leadingMonomial();
            e = m.getKey();
            //logger.info("red = " + e);
            a = m.getValue();
            for (i = 0; i < l; i++) {
                mt = e.multipleOf(htl[i]);
                if (mt)
                    break;
            }
            if (!mt) {
                //logger.debug("irred");
                //T = new OrderedMapPolynomial( a, e );
                R = (GenSolvablePolynomial<C>) R.sum(a, e);
                S = (GenSolvablePolynomial<C>) S.subtract(a, e);
                // System.out.println(" S = " + S);
            } else {
                //logger.debug("red");
                e = e.subtract(htl[i]);
                //a = a.divide( (C)lbc[i] );
                Q = p[i].multiply(e);
                a = a.divide(Q.leadingBaseCoefficient());
                Q = Q.multiply(a);
                S = (GenSolvablePolynomial<C>) S.subtract(Q);
            }
        }
        return R;
    }


    /**
     * RightNormalform with recording.
     * @param row recording matrix, is modified.
     * @param Pp a polynomial list for reduction.
     * @param Ap a polynomial.
     * @return nf(Pp,Ap), the right normal form of Ap wrt. Pp.
     */
    @SuppressWarnings("unchecked")
    public GenSolvablePolynomial<C> rightNormalform(List<GenSolvablePolynomial<C>> row,
            List<GenSolvablePolynomial<C>> Pp, GenSolvablePolynomial<C> Ap) {
        if (Pp == null || Pp.isEmpty()) {
            return Ap;
        }
        if (Ap == null || Ap.isZERO()) {
            return Ap;
        }
        int l = Pp.size();
        GenSolvablePolynomial<C>[] P = (GenSolvablePolynomial<C>[]) new GenSolvablePolynomial[l];
        synchronized (Pp) {
            //P = Pp.toArray();
            for (int i = 0; i < Pp.size(); i++) {
                P[i] = Pp.get(i);
            }
        }
        ExpVector[] htl = new ExpVector[l];
        Object[] lbc = new Object[l]; // want <C>
        GenSolvablePolynomial<C>[] p = (GenSolvablePolynomial<C>[]) new GenSolvablePolynomial[l];
        Map.Entry<ExpVector, C> m;
        int j = 0;
        int i;
        for (i = 0; i < l; i++) {
            p[i] = P[i];
            m = p[i].leadingMonomial();
            if (m != null) {
                p[j] = p[i];
                htl[j] = m.getKey();
                lbc[j] = m.getValue();
                j++;
            }
        }
        l = j;
        ExpVector e;
        C a;
        boolean mt = false;
        GenSolvablePolynomial<C> zero = Ap.ring.getZERO();
        GenSolvablePolynomial<C> R = Ap.ring.getZERO();

        GenSolvablePolynomial<C> fac = null;
        // GenSolvablePolynomial<C> T = null;
        GenSolvablePolynomial<C> Q = null;
        GenSolvablePolynomial<C> S = Ap;
        while (S.length() > 0) {
            m = S.leadingMonomial();
            e = m.getKey();
            a = m.getValue();
            for (i = 0; i < l; i++) {
                mt = e.multipleOf(htl[i]);
                if (mt)
                    break;
            }
            if (!mt) {
                //logger.debug("irred");
                R = (GenSolvablePolynomial<C>) R.sum(a, e);
                S = (GenSolvablePolynomial<C>) S.subtract(a, e);
                // System.out.println(" S = " + S);
            } else {
                e = e.subtract(htl[i]);
                //logger.info("red div = " + e);
                //a = a.divide( (C)lbc[i] );
                //Q = p[i].multiply( a, e );
                Q = p[i].multiply(e);
                a = a.divide(Q.leadingBaseCoefficient());
                Q = Q.multiply(a);
                S = (GenSolvablePolynomial<C>) S.subtract(Q);
                fac = row.get(i);
                if (fac == null) {
                    fac = (GenSolvablePolynomial<C>) zero.sum(a, e);
                } else {
                    fac = (GenSolvablePolynomial<C>) fac.sum(a, e);
                }
                row.set(i, fac);
            }
        }
        return R;
    }

}
